An unusual nicotinamide derivative, 4-pyridone-3-carboxamide ribonucleoside (4PYR), is a novel endothelial toxin and oncometabolite.

Our recent studies identified a novel pathway of nicotinamide metabolism that involves 4-pyridone-3-carboxamide-1-ß-D-ribonucleoside (4PYR) and demonstrated its endothelial cytotoxic effect. This study tested the effects of 4PYR and its metabolites in experimental models of breast cancer. Mice were divided into groups: 4T1 (injected with mammary 4T1 cancer cells), 4T1 + 4PYR (4PYR-treated 4T1 mice), and control, maintained for 2 or 21 days. Lung metastasis and endothelial function were analyzed together with blood nucleotides (including 4PYR), plasma amino acids, nicotinamide metabolites, and vascular ectoenzymes of nucleotide catabolism. 4PYR metabolism was also evaluated in cultured 4T1, MDA-MB-231, MCF-7, and T47D cells. An increase in blood 4PYR in 4T1 mice was observed at 2 days. 4PYR and its metabolites were noticed after 21 days in 4T1 only. Higher blood 4PYR was linked with more lung metastases in 4T1 + 4PYR vs. 4T1. Decreased L-arginine, higher asymmetric dimethyl-L-arginine, and higher vascular ecto-adenosine deaminase were observed in 4T1 + 4PYR vs. 4T1 and control. Vascular relaxation caused by flow-dependent endothelial activation in 4PYR-treated mice was significantly lower than in control. The permeability of 4PYR-treated endothelial cells was increased. Decreased nicotinamide but enhanced nicotinamide metabolites were noticed in 4T1 vs. control. Reduced N-methylnicotinamide and a further increase in Met2PY were observed in 4T1 + 4PYR vs. 4T1 and control. In cultured breast cancer cells, estrogen and progesterone receptor antagonists inhibited the production of 4PYR metabolites. 4PYR formation is accelerated in cancer and induces metabolic disturbances that may affect cancer progression and, especially, metastasis, probably through impaired endothelial homeostasis. 4PYR may be considered a new oncometabolite.

Effect of AMP-deaminase 3 knock-out in mice on enzyme activity in heart and other organs.

Recent findings suggest that inhibition of AMP-deaminase (AMPD) could be effective therapeutic strategy in heart disease associated with cardiac ischemia. To establish experimental model to study protective mechanisms of AMPD inhibition we developed conditional, cardiac specific knock-outs in Cre recombinase system. AMPD3 floxed mice were crossed with Mer-Cre-Mer mice. Tamoxifen was injected to induce Cre recombinase. After two weeks, hearts, skeletal muscle, liver, kidney, and blood were collected and activities of AMPD and related enzymes were analyzed using HPLC-based procedure. We demonstrate loss of more than 90% of cardiac AMPD activity in the heart of AMPD3-/-mice while other enzymes of nucleotide metabolism such as adenosine deaminase, purine nucleoside phosphorylase were not affected. Surprisingly, activity of AMPD was also reduced in the erythrocytes and in the kidney by 20%-30%. No change of AMPD activity was observed in the skeletal muscle and the liver.

Effect of 4-pyridone-3-carboxamide ribonucleoside (4PYR)-potential cardiovascular toxin in perfused rat heart.

We recently described a new nicotinamide derivative: 4-pyridone-3-carboxamide ribonucleoside (4PYR) and its conversion to intracellular metabolites (4PYR monophosphate: 4PYMP and 4PYR adenylate diphosphate: 4PYRAD). The aim of this study was to clarify the metabolism and physiological effects of brief exposure to 4PYR in perfused rat heart. Rat hearts were perfused in Langendorff mode. After 15 min equilibration, 100 µM 4PYR (or solvent in controls) was infused into coronary circulation for 5 min. Coronary flow was recorded with electromagnetic flow meter and left ventricular mechanical function was assessed with intraventricular baloon by constructing pressure-volume relations. After perfusion hearts were freeze-clamped and analyzed using HPLC for phosphocreatine, creatine, ATP with metabolites as well as 4PYR metabolites. 4PYR infused into the coronary circulation was rapidly converted in the heart into 4PYMP and 4PYRAD with concentrations reaching 85.6±46.9 and 43.9±6.4 nmol/g dry weight, respectively, while control concentrations were below 20 nmol/g. 4PYR had no effect on baseline coronary flow (11.9±2.3 ml/min versus 11.0±2.7 ml/min in control) or stimulated by shear stress (23.2±4.5 ml/min versus 23.1±5.2 ml/min in control). Both systolic and diastolic left ventricular mechanical function were not affected by 4PYR. No difference was noted for heart rate. Myocardial concentrations of ATP or phosphocreatine were also not affected by 4PYR. We conclude that 4PYR has no immediate effect on coronary endothelium or cardiomyocyte functions such as coronary flow, rhythm, diastolic properties, or contractility despite rapid incorporation into intracellular metabolites. This study also indicates the lack of effect on purinergic receptors.

Activity of AMP-regulated protein kinase and AMP-deaminase in the heart of mice fed high-fat diet.

AMP-regulated protein kinase (AMPK) is involved in numerous regulatory processes and its role in control of cardiac energy metabolism is particularly important. This activity could be affected by AMP-deaminase (AMPD) since substrate of AMPD is AMPK activator. Hearts of male mouse, fed for six weeks with normal or high-fat diet, were fractionated to enrich AMPK activity. Purified fraction was incubated with AMARA peptide for up to 5 minutes and then conversion of AMARA to pAMARA was determined by liquid chromatography-mass spectrometry (LC/MS) using mass detector. Activity of AMPK in heart was 0.038±0.012 pmol/min/mg protein for mice fed high-fat diet and that was not different to control (0.032±0.01 pmol/min/mg protein). We observed change in AMPD activity. It was 5.39±1.5 nmol/mg tissue/min in heart of mice fed high-fat diet while in heart of mice fed low-fat diet it was 2.29±0.32 nmol/mg tissue/min. Data we present indicate that while total AMPK activity is not changed decrease in AMPD activity may affect AMPK signaling in diabetic heart.

AMP deaminase 1 gene polymorphism and heart disease-a genetic association that highlights new treatment.

Nucleotide metabolism and signalling is directly linked to myocardial function. Therefore analysis how diversity of genes coding nucleotide metabolism related proteins affects clinical progress of heart disease could provide valuable information for development of new treatments. Several studies identified that polymorphism of AMP deaminase 1 gene (AMPD1), in particular the common C34T variant of this gene was found to benefit patients with heart failure and ischemic heart disease. However, these findings were inconsistent in subsequent studies. This prompted our detailed analysis of heart transplant recipients that revealed diverse effect: improved early postoperative cardiac function associated with C34T mutation in donors, but worse 1-year survival. Our other studies on the metabolic impact of AMPD1 C34T mutation revealed decrease in AMPD activity, increased production of adenosine and de-inhibition of AMP regulated protein kinase. Thus, genetic, clinical and biochemical studies revealed that while long term attenuation of AMPD activity could be deleterious, transient inhibition of AMPD activity before acute cardiac injury is protective. We suggest therefore that pharmacological inhibition of AMP deaminase before transient ischemic event such as during ischemic heart disease or cardiac surgery could provide therapeutic benefit.